Marvin D A, Hale R D, Nave C, Helmer-Citterich M
Department of Biochemistry, University of Cambridge, U.K.
J Mol Biol. 1994 Jan 7;235(1):260-86. doi: 10.1016/s0022-2836(05)80032-4.
The filamentous bacteriophages are flexible rods about 1 to 2 microns long and 6 nm in diameter, with a helical shell of protein subunits surrounding a DNA core. The approximately 50-residue coat protein subunit is largely alpha-helix and the axis of the alpha-helix makes a small angle with the axis of the virion. The protein shell can be considered in three sections: the outer surface, occupied by the N-terminal region of the subunit, rich in acidic residues that interact with the surrounding solvent and give the virion a low isoelectric point; the interior of the shell, including a 19-residue stretch of apolar side-chains, where protein subunits interact mainly with each other; and the inner surface, occupied by the C-terminal region of the subunit, rich in basic residues that interact with the DNA core. The fact that virtually all protein side-chain interactions are between different subunits in the coat protein array, rather than within subunits, makes this a useful model system for studies of interactions between alpha-helix subunits in a macromolecular assembly. We describe molecular models of the class I filamentous bacteriophages. This class includes strains fd, f1, M13 (these 3 very similar strains are members of the Ff group), If1 and IKe. Our model of fd has been refined to fit quantitative X-ray fibre diffraction data to 30 A resolution in the meridional direction and 7 A resolution in the equatorial direction. A simulated 3.3 A resolution diffraction pattern from this model has the same general distribution of intensity as the experimental diffraction pattern. The observed diffraction data at 7 A resolution are fitted much better by the calculated diffraction pattern of our molecular model than by that of a model in which the alpha-helix subunit is represented by a rod of uniform density. The fact that our fd model explains the fd diffraction data is only part of our structure analysis. The atomic details of the model are supported by non-diffraction data, in part previously published and in part newly reported here. These data include information about permitted or forbidden side-chain replacements, about the effect of chemical modification, and about spectroscopic experiments.(ABSTRACT TRUNCATED AT 400 WORDS)
丝状噬菌体是长约1至2微米、直径6纳米的柔性杆状病毒,其蛋白质亚基构成的螺旋外壳围绕着DNA核心。约含50个残基的外壳蛋白亚基主要为α螺旋结构,α螺旋的轴与病毒粒子的轴呈小角度。蛋白质外壳可分为三个部分:外表面,由亚基的N端区域占据,富含酸性残基,与周围溶剂相互作用,使病毒粒子具有低等电点;外壳内部,包括一段19个残基的非极性侧链延伸段,蛋白质亚基主要在此处相互作用;内表面,由亚基的C端区域占据,富含碱性残基,与DNA核心相互作用。实际上,所有蛋白质侧链相互作用都发生在外壳蛋白阵列中的不同亚基之间,而非亚基内部,这使得它成为研究大分子组装中α螺旋亚基间相互作用的有用模型系统。我们描述了I类丝状噬菌体的分子模型。这类包括fd、f1、M13菌株(这3个非常相似的菌株是Ff组的成员)、If1和IKe。我们对fd的模型进行了优化,使其在子午线方向上与30埃分辨率的定量X射线纤维衍射数据拟合,在赤道方向上与7埃分辨率的数据拟合。该模型模拟的3.3埃分辨率衍射图谱与实验衍射图谱具有相同的强度总体分布。与用密度均匀的棒表示α螺旋亚基的模型相比,我们分子模型的计算衍射图谱能更好地拟合7埃分辨率下观测到的衍射数据。我们的fd模型能够解释fd衍射数据,这只是我们结构分析的一部分。该模型的原子细节得到了非衍射数据的支持,部分数据此前已发表,部分在此新报道。这些数据包括关于允许或禁止的侧链替换、化学修饰的影响以及光谱实验的信息。(摘要截选至400字)
